CN113965968B - Method for link switching in a wireless communication system, wireless communication device and network node - Google Patents

Abstract

The wireless communication device (16) is configured for use in a wireless communication system. In this regard, the device (16) is configured to receive a command (22), the command (22) instructing the device (16) to perform a link switch (24) from a source link (20A) to a target link (20B) in response to satisfaction of a condition. The command (22) may indicate a target link configuration (26) relative to a source link configuration. The device (16) is further configured to store information (30) from which information (30) the target link configuration (26) indicated by the command (22) can be determined irrespective of any change in the source link configuration that occurs after receiving the command (22). In some embodiments, the device (16) is configured to perform a link handoff (24) from the source link (20A) to the target link (20B) using the target link configuration (26) determined from the stored information (30) in response to satisfaction of the condition.

Description

Method for link switching in a wireless communication system, wireless communication device and network node

The present application is a divisional application of chinese patent application (201780083522.4), the filing date of the original application is (12 months, 21 days in 2017), the priority date is (16 days in 2017, 1 month), and the name of the present application is "link switching in wireless communication system".

RELATED APPLICATIONS

The present application claims priority from U.S. provisional patent application Ser. No. 62/446,822 filed on 1/16 of 2017, the entire contents of which are incorporated herein by reference.

Technical Field

The present application relates generally to wireless communication systems and, in particular, to link switching in wireless communication systems.

Background

As channel conditions of a wireless communication device change, the device may switch (e.g., hand over or reselect) from one wireless link to another wireless link in order to maintain service continuity. A device may, for example, switch from accessing the system via one access node, cell, sector, or beam (any of which may act as a "link") to accessing the system via a different access node, cell, sector, or beam. To this end, when the channel conditions on the link to which the device is currently accessing the system deteriorate, the system may evaluate to which different candidate target link (if any) the device should switch. In this regard, the device may perform measurements on different candidate target links and report these measurements to another node in the network (e.g., a serving access node) so that the other node may make a link handoff decision. Once a link switch decision is made, the node may command the device to switch to the selected target link.

The known link switching methods are susceptible to high delays, which proves to be particularly problematic when the link switching has to be performed quickly, for example before the quality of the service link is excessively reduced. However, signaling schemes that reduce link handoff delays while remaining effective prove challenging.

Disclosure of Invention

According to one or more embodiments herein, a network node sends a command to a wireless communication device to switch from a source link to a target link in response to satisfaction of a condition (e.g., as detected by the wireless communication device). By conditionally commanding a link switch in this way, commands can be sent to the device earlier in time than in conventional approaches in order to improve the robustness of the link switch to degraded source link quality. Further, some embodiments herein effectively signal the target link configuration relative to the source link configuration, but still ensure that the signaled target link configuration is recoverable or otherwise determinable even if the source link configuration changes (e.g., a transition period between when a link handoff is conditionally commanded and when a link handoff is performed).

More specifically, embodiments herein include a method performed by a wireless communication device configured for a wireless communication system. The method may include receiving a command that instructs the wireless communication device to perform a link handoff from a source link to a target link in response to satisfaction of a condition. The command may indicate a target link configuration relative to a source link configuration. The method may further comprise storing information from which the target link configuration indicated by the command can be determined without regard to any change in the source link configuration that occurs after receipt of the command. In some embodiments, the method may further include performing one or more operations based on the stored information. In one example, performing one or more operations based on stored information, for example, may include: in response to satisfaction of the condition, a link handoff from the source link to the target link is performed using the target link configuration determined from the stored information.

In some embodiments, the command includes relative reconfiguration information indicating the target link configuration relative to the source link configuration. The relative reconfiguration information may, for example, include one or more parameter values that are different between the target link configuration and the source link configuration, and not include one or more parameter values that are the same between the target link configuration and the source link configuration. In any event, the information from which the target link configuration indicated by the command can be determined may include the relative reconfiguration information and/or the source link configuration at the time the command is received.

In some embodiments, the method may further comprise: the target link configuration is determined from the stored information in response to the condition being met. That is, the determination of the target link configuration can be deferred until the condition for link switching is satisfied. In contrast, in other embodiments, the target link configuration indicated by the command may be determined in response to receiving the command or in response to determining that the source link configuration is to be changed. Then, in these and other embodiments, the method may include storing the determined target link configuration as stored information.

In any of these embodiments, the method may include: after storing the information from which the target link configuration indicated by the command can be determined, the source link configuration is changed, and the stored information is retained regardless of the change in the source link configuration.

In some embodiments, the method may include: associating the stored information with the condition, receiving an update to the condition, and updating the condition according to the received update while retaining the stored information and the association of the condition with the stored information. Alternatively or additionally, the method may comprise: associating the stored information with a validity timer for the command, receiving an update to the validity timer, and updating the validity timer according to the received update while retaining the stored information and the association of the validity timer with the stored information.

In any of these embodiments, the target link configuration may specify a random access configuration for random access to the target link.

In some embodiments, the condition is satisfied when the signal measurement for the target link exceeds the signal measurement for the source link by at least a predetermined amount.

In some embodiments, the target link configuration is a radio resource control, RRC, configuration for the target link.

In some embodiments, the condition is a measurement configuration associated with a measurement event. For example, in some embodiments, the measurement configuration is provided explicitly in the conditional switch command. Alternatively or additionally, the measurement configuration is part of the source link configuration, wherein the conditional handover command includes a reference to the measurement configuration.

Embodiments also include corresponding apparatuses, computer programs, and computer-readable media.

Embodiments include, for example, a wireless communication device configured for use in a wireless communication system. In this regard, the wireless communication device is configured to receive a command that instructs the wireless communication device to perform a link handoff from a source link to a target link in response to satisfaction of a condition. The command may indicate a target link configuration relative to a source link configuration. The wireless communication device is further configured to store information from which the target link configuration indicated by the command can be determined without regard to any change in the source link configuration that occurs after receiving the command. In some embodiments, the wireless communication device is further configured to perform one or more operations based on the stored information. In one example, for example, the wireless communication device is configured to perform a link handoff from the source link to the target link using the target link configuration determined from the stored information in response to satisfaction of the condition.

Embodiments also include a method performed by a network node configured for a wireless communication system. The method includes sending a command that instructs the wireless communication device to perform a link handoff from a source link to a target link in response to satisfaction of a condition, wherein the command indicates a target link configuration relative to a source link configuration. The method may further comprise: after sending the command, the source link configuration is changed. The method may further comprise: after changing the source link configuration, an update command is sent indicating an updated target link configuration relative to the source link configuration prior to the source link configuration change.

In some embodiments, the method further comprises signaling the update command to indicate the updated target link configuration relative to the source link configuration prior to the change in the source link configuration.

In some embodiments, the command includes relative reconfiguration information indicating the target link configuration relative to the source link configuration when the command is sent.

In some embodiments, the relative reconfiguration information includes one or more parameter values that differ between the target link configuration and the source link configuration when the command is sent, and does not include one or more parameter values that are the same between the target link configuration and the source link configuration when the command is sent.

In some embodiments, the target link configuration specifies a random access configuration for random access to the target link.

In some embodiments, the condition is satisfied when the signal measurement for the target link exceeds the signal measurement for the source link by at least a predetermined amount.

In some embodiments, the target link configuration is a radio resource control, RRC, configuration for the target link.

Embodiments also include corresponding apparatuses, computer programs, and computer-readable media.

For example, embodiments include a network node configured for a wireless communication system. The network node is configured to send a command instructing the wireless communication device to perform a link switch from a source link to a target link in response to satisfaction of a condition, wherein the command indicates a target link configuration relative to a source link configuration. The network node is further configured to change the source link configuration after sending the command. The network node is further configured to send an update command after changing the source link configuration, the update command indicating an updated target link configuration relative to the source link configuration prior to the source link configuration change.

Drawings

Fig. 1 is a block diagram of a wireless communication system including a wireless device and a network node, in accordance with some embodiments;

fig. 2 is a logic flow diagram of a method performed by a wireless device in accordance with some embodiments;

fig. 3 is a call signaling diagram of a process for conditional link switching in accordance with some embodiments;

fig. 4 is a call signaling diagram of a process for conditional link switching according to other embodiments;

fig. 5A is a block diagram of a wireless device according to some embodiments;

fig. 5B is a block diagram of a wireless device according to other embodiments;

FIG. 6 is a logic flow diagram of a method performed by a network node in accordance with some embodiments;

fig. 7A is a block diagram of a network node according to some embodiments;

fig. 7B is a block diagram of a network node according to other embodiments.

Detailed Description

Fig. 1 illustrates a wireless communication system 10 in accordance with one or more embodiments. As shown, a system 10 (e.g., a 5G system) may include AN Access Network (AN) 12 and a Core Network (CN) 14.AN 12 wirelessly connects a wireless communication device 16 (or simply "wireless device 16") to CN 14.CN 14 in turn connects wireless device 16 to one or more external networks (not shown), such as a public switched telephone network and/or a packet data network (e.g., the internet).

AN 12 provides a link via which wireless device 16 may wirelessly access system 10, for example using uplink and/or downlink communications. The AN 12 may provide links, for example, in the form of access nodes (e.g., base stations), cells, sectors, beams, etc. Some links may provide wireless coverage over different geographical areas.

Network node 18 controls the links used by device 16 to access system 10. The network node 18 may be in the AN 12 (e.g., in the form of a base station) or in the CN 14 (e.g., in the form of a Mobility Management Entity (MME) or AN Access and Mobility Function (AMF)). The network node 18 may control which link the device 16 uses by, for example, deciding which link the device 16 is to switch (e.g., hand over or reselect) from accessing the system 10 via one link ("source" link) to accessing the system 10 via another link ("target" link). Network node 18 may select the target link from a set of multiple links that network node 18 considers to be candidates for the target link.

However, in some embodiments, rather than unconditionally commanding the device 16 to switch from the source link to the selected target link, the network node 18 conditionally commands the device 16 to perform such a link switch. In this regard, fig. 1 illustrates that the wireless communication device 16 may receive the conditional handoff command 22, for example, from the network node 18 or via the network node 18. For example, in the case where the link handoff is a handoff, command 22 may be a conditional handoff command. Regardless, conditional handoff command 22 as shown "conditionally" instructs device 16 to perform link handoff 24 from source link 20A to target link 20B. The device 16 performs the link switch 24 in particular in response to the satisfaction of a condition (e.g., in response to the device 16 detecting that the signal strength or quality of the target link exceeds the signal strength or quality of the source link by at least a predetermined amount). In some embodiments, device 16 may autonomously perform link switch 24, for example, once device 16 itself detects satisfaction of a condition. Conditionally performing the link switch 24 in this manner can, for example, improve the robustness of the link switch 24 against degraded source link conditions.

Fig. 1 also shows that in some embodiments, conditional switch command 22 indicates a target link configuration 26, e.g., for target link 20B by device 16, wherein command 22 conditionally commands device 16 to switch to target link 20B. The target link configuration 26 may be a Radio Resource Control (RRC) configuration, e.g., to be provided via an RRC connection reconfiguration (RRCConnectionReconfiguration) message in an LTE embodiment or via an RRC reconfiguration (rrcrecon configuration) message in a New Radio (NR) embodiment, for example, for the target link 20B. The target link configuration 26 may, for example, contain configuration parameters for data radio bearers, signaling radio bearers, medium Access Control (MAC), radio Link Control (RLC), packet Data Convergence Protocol (PDCP), and/or physical layers for the target link 20B. The configuration parameters may be used, for example, for data and control channels, for example, for random access channels. In this regard, the target link configuration 26 may specify a random access configuration (e.g., in terms of a random access preamble, etc.) that the device 16 will use to connect to the target link 20B. In this regard, the random access configuration may include one or more sets of parameters that define when (in time), where (in frequency), and/or how (e.g., in terms of code/preamble, power, periodicity) the device 16 may transmit a random access request for connection to the target link 20B.

Regardless of the particular type of configuration 26, the conditional handover command 22 may indicate a target link configuration 26 relative to a source link configuration 28, such as the (e.g., RRC) configuration 28 used by the device 16 for the source link 20A, wherein the command 22 conditionally commands the device 16 to handover from the source link 20A. The command 22 may, for example, include (or otherwise be associated with) relative (or "delta") reconfiguration information defining a target link configuration 26 relative to a source link configuration 28. In some embodiments, the relative reconfiguration information includes, for example, one or more parameter values that are different between the target link configuration 26 and the source link configuration 28, and does not include the same one or more parameter values between the target link configuration 26 and the source link configuration 28. In this regard, the command 22 effectively assumes that the device 16 already knows the parameter values of the target link configuration 26, which are the same as the parameter values of the source link configuration 28 at the time the command 22 was received, thus effectively avoiding unnecessary signaling of these parameter values to the device 16. In this case, device 16 may be configured to form, derive, or otherwise determine target link configuration 26 from the parameter values included in command 22 in combination with any parameter values from source link configuration 27 not included in command 22.

In some embodiments, signaling the target link configuration 26 relative to the source link configuration 28 in this manner may prove effective. However, unless properly considered, a change in the source link configuration 28 may threaten the target link configuration, which in turn changes the signaling detected by the device 16. For example, the construction of the command 22 may be based on the source link configuration 28 that is (currently) present at the time of command construction, and changes in the source link configuration 28 that occur after command construction may affect the device 16 in interpreting what target link configuration is signaled by the command 22. This is especially true because the switch command 22 is conditional in nature. For example, if the device 16 simply waits until a condition for a link switch occurs before determining the target link configuration 26 for signaling, the device 16 may determine a target link configuration that is different from the target link configuration for actual signaling if the source link configuration 28 has changed during the transition.

To account for these and other issues surrounding configuration signaling, the device 16 in some embodiments herein stores information 30 from which information 30 the target link configuration 26 indicated by the conditional handover command 22 can be determined without regard to any changes in the source link configuration 28 that occur after the conditional handover command 22 is received. That is, even if the source link configuration 28 changes after the device 16 receives the command 22, the stored information 30 enables the device 16 to determine the signaled target link configuration 26. In some embodiments, for example, device 16 may memorize or retain stored information 30 (e.g., in memory) even if source link configuration 28 is changed. With this information 30 retained, the device 16 may be configured to determine 32 a signalled target link configuration 26 from the stored information 30, e.g. as opposed to referencing any current source link configuration 28, since the source link configuration 28 may have changed since the command 22 was constructed. Thus, regardless of whether the source link configuration 28 changes after receiving the command 22, the device 16 may still determine the target link configuration 26 indicated by the command 22.

In some embodiments, for example, the stored information 30 includes the source link configuration 28 at the time the command 22 was received, or at least a portion thereof, such as the source link configuration 28 that was reserved or remembered at the time the conditional switch command 22 was received. The device 16 may store the source link configuration 28, in whole or in part, for example in response to receiving the conditional switch command 22. Then, at a later time (e.g., when the condition is met), the device 16 may determine the target link configuration 26 indicated by the conditional switch command 22 (retrospectively) by referring to the stored source link configuration 28, instead of the current source link configuration that may have changed.

Alternatively or additionally, the stored information 30 may include the relative reconfiguration information mentioned above. The stored information 30 in this case may include one or more parameters of the target link configuration 26 that are different from the parameters of the source link configuration 28 at the time the command was received. When the relative reconfiguration information is stored with the source link configuration 28, the stored information 30 thereby memorizes or retains the target link configuration 26 signaled by the command 22 in a "relative" form.

In contrast, in other embodiments, the device 16 may memorize or retain the target link configuration 26 in an "absolute" form (i.e., in a form that is not relative to the source link configuration 28). In some embodiments, for example, the device 16 determines the target link configuration 26 indicated by the conditional switch command 22 and stores the determined target link configuration 26 as stored information 30. The stored information 30 is then in a sense an "absolute" target link configuration 26 that does not depend on any relatedness to the source link configuration 28, as opposed to the "relative" target link configuration 26 signaled in the command 22 with respect to the source link configuration 28.

In any event, device 16 may determine target link configuration 26 for storage in an "absolute" form at any time after receiving command 22 and before source link configuration 28 changes. In one embodiment, for example, the device 16 is configured to determine the target link configuration 26 indicated by the conditional switch command 22 in response to (e.g., upon) receiving the command 22. In this way, the source link configuration 28 will not change, thereby ensuring that the determined target link configuration 26 represents the configuration to be signaled. In contrast, in other embodiments, device 16 may wait to determine target link configuration 26 until source link configuration 28 is about to be changed. The device 16 may determine the target link configuration 26 indicated by the conditional handover command 22, for example, in response to receiving a reconfiguration message indicating that the source link configuration 28 is to be changed. In either approach, however, the device 16 stores the determined target link configuration 26 to remember the configuration 26 for the potential link switch 24 when the relevant condition is met.

The target link configuration 26 sent using stored information memory signaling may mean that the device 16 retains the stored information 30 even if the source link configuration 28 changes. That is, in some embodiments, device 16 may change source link configuration 28 after storing information 30 (e.g., as indicated by network node 18), but may retain stored information 30 regardless of such change in source link configuration 28.

Similarly, the device 16 may retain the stored information 30 even if the network node 18 signals an update to the command 22, e.g., changes the conditions for performing the link switch 24 and/or changes the validity timer of the command 22. In some embodiments, for example, device 16 may associate stored information 30 with conditions for performing link switch 24. In this case, when device 16 receives an update to a condition, device 16 may update the condition according to the received update while retaining stored information 30 and the association of stored information 30 with the (now updated) condition. Alternatively or additionally, the device 16 may associate the stored information 30 with a validity timer for the command 22, for example, indicating a duration that the command 22 remains valid. In this case, when the device 16 receives an update to the validity timer (e.g., extending the time that the command 22 is valid), the device 16 may update the validity timer based on the received update while retaining the stored information 30 and the association of the stored information 30 with the (now updated) validity timer.

However, under certain conditions, such as when the stored information is no longer needed, the stored information 30 may be discarded or replaced. For example, in some cases, the link switch 24 to the target link 20B may be canceled before the condition is satisfied. In some embodiments, for example, device 16 may cancel link switch 24 in response to receiving a command to specifically cancel link switch 24, or cancel any link switches that have not yet met the respective conditions as a whole. In other embodiments, device 16 may cancel link switch 24 in response to receiving a command to perform a link switch from source link 20A to a different target link or in response to successfully performing (or signaling an acknowledgement of) a link switch from source link 20A to a different target link. Regardless, in response to canceling the link switch 24, the device 16 may discard the stored information 30, for example, because it is no longer necessary to determine the target link configuration 26. However, in some embodiments, if device 16 does determine that stored information 30 is not needed, device 16 may simply discard stored information 30, e.g., as opposed to assuming only when link switch 24 is canceled.

Indeed, in these and other embodiments, device 16 may receive one or more conditional handoff commands 22 that instruct device 16 to perform a link handoff from source link 20A to a different target link in response to satisfaction of the respective conditions. For respective target links, one or more commands may indicate respective target link configurations, which may be the same or different among the target links. Thus, the device 16 may store information from which each respective target link configuration can be determined. For example, where respective target link configurations are indicated with respect to the same source link configuration 28, in some embodiments, the device 16 may store the source link configuration 28 from which the respective target link configurations can be determined (e.g., in conjunction with relative reconfiguration information associated with respective target links). Thus, with multiple target link configurations determinable from the same stored source link configuration 28, the device 16 may discard the stored information only if it is determined that there is no target link configuration determinable from the stored source link configuration 28. For example, if a link handoff to one of the target links is canceled, but at least one other link handoff to the other target link is still pending, device 16 may continue to retain the stored information (at least to the extent necessary to determine the target link configuration for the pending link handoff).

Under certain conditions, in other embodiments, device 16 may simply update the stored information rather than discard it. For example, device 16 may receive an update command for a target link indicating an updated target link configuration relative to the same source link configuration. In this case, the device 16 may replace the stored information 30 with information from which the updated target link configuration can be determined, irrespective of any changes in the source link configuration that occur after receiving the update command.

In view of the above modifications and variations, fig. 2 generally illustrates the processing performed by the wireless communication device 16 according to some embodiments. As shown, the process may include receiving a command 22 that instructs the wireless communication device 16 to perform a link switch 24 from the source link 20A to the target link 20B in response to satisfaction of a condition (block 100). The command 22 may indicate a target link configuration 26 relative to a source link configuration 28. The process shown in fig. 2 may also include storing information 30 from which information 30 the target link configuration 26 indicated by the command 22 can be determined without regard to any changes in the source link configuration 28 that occur after the command 22 is received (block 110).

In some embodiments, processing may also include performing one or more operations based on the stored information 30 (block 120). In one embodiment, for example, performing one or more operations based on the stored information 30 may include: in response to satisfaction of the condition, a link switch 24 from the source link 20A to the target link 20B is performed using the target link configuration 26 determined from the stored information 30.

In other embodiments, these one or more operations may involve managing the stored information 30. For example, device 16 may be configured to discard or delete stored information 30 if stored information 30 is no longer suitable for pending link handoffs, e.g., if a conditional link handoff is canceled before the relevant condition is met. In some embodiments, for example, one or more operations include canceling a link handoff to a target link before a condition is met, and discarding stored information in response to such cancellation. For example, cancellation of a conditional link handoff may occur in response to receiving a cancel handoff command, receiving a handoff command to handoff to a different target link, and/or successfully performing handoff to a different link or signaling an acknowledgment of handoff to a different link.

One or more additional embodiments will now be described in the context of system 10 being a 5G or New Radio (NR) system, link being a cell, link handover 24 being a handoff, and link configuration being an RRC configuration.

In more detail, one of the main goals of New Radios (NRs) is to provide more capacity for operators to meet the ever-increasing traffic demands and various applications. Thus, NR will be able to operate at high frequencies of 6GHz up to 60 and even 100 GHz. Some new frequency bands will have more challenging propagation characteristics, such as lower diffraction and higher outdoor/indoor penetration loss, than the current frequency bands allocated to Long Term Evolution (LTE). Thus, the ability of the signal to propagate around the corner and penetrate the wall is weak. In addition, in the high frequency band, atmospheric/rain fade and higher body loss (body loss) make the coverage of the NR signal more irregular.

Fortunately, operation at higher frequencies allows for the use of smaller antenna elements, which allows for an antenna array with many antenna elements. Such an antenna array facilitates beamforming, wherein multiple antenna elements are used to form a narrow beam and thereby compensate for challenging propagation characteristics.

While beamforming solutions provide link budget gain, the reliability of systems that rely purely on beamforming and operate at higher frequencies can be challenging because coverage can be more sensitive to both time and spatial variations. As a result, the signal-to-interference-plus-noise ratio (SINR) of such a narrow link may drop much faster than in the case of LTE. Therefore, the serving cell may not be able to transmit the handover command in time. Decreasing the Time To Trigger (TTT) parameter and measurement hysteresis reduces the handover failure rate but also results in a higher ping-pong probability. Thus, the rapidly deteriorating link quality prevents the delivery of a Handover (HO) command from the source cell to the User Equipment (UE), which ultimately results in handover failure. In NR, these effects will be more pronounced when operating in the higher frequency band. In order to ensure that the NR provides mobility that is at least as robust as LTE, such as a low or lower handover failure (HOF) rate, there is a need to pay attention to mobility robustness in the NR system.

In LTE and NR, different solutions for increasing mobility robustness have been discussed. One area of solution is based on the dual connectivity introduced in LTE Rel-12. In dual connectivity, the UE connects to two network nodes simultaneously. This allows for improved mobility robustness by serving control plane traffic (e.g. for measurement reporting and handover commands) by a more robust macro layer on a lower frequency and providing capacity boosting by higher layers. This feature is called User Plane (UP)/Control Plane (CP) separation. One variant of dual connectivity is the RRC diversity feature, which allows control plane signaling to be sent on both nodes. This increases diversity in the time and space domains, thereby increasing robustness.

One problem with the dual connectivity solution is that the UE must have two connections. This can be problematic as network resources are consumed more. Furthermore, dual connectivity requires two different receive/transmit (RX/TX) chains on the UE side, which brings about device manufacturing costs. Therefore, alternative solutions should also be considered.

To avoid undesirable dependencies on the serving radio link at the time (and radio conditions) at which the UE should perform the handover, the NR according to some embodiments may provide RRC signaling for handover to the UE earlier than conventional. To this end, a handover command may be associated with a condition. Once the condition is met, the UE may perform a handover according to the provided handover command.

Such conditions may be based, for example, on a comparison of measurements (also referred to as "measurement events") acquired by the UE. An event or condition is generally expressed as an equation, and if the equation is "true," the event or condition is considered satisfied. An example of a measurement event is an equation that compares a measurement quantity (typically "signal strength" or "signal quality") (e.g., "rsrp neighbor") determined for a neighboring cell with a measurement quantity (e.g., "rsrpServing") determined for a serving cell. In addition to these two measurements, there may be additional thresholds or hysteresis (e.g., threshold X). If "rsrpNeighbour > rsrpServing+threshldX", then the event is considered satisfied. Thus, in this example, the UE will perform handover when the signal strength (RSRP) of the neighboring cell becomes X (dB) or more better than the signal strength of the serving cell.

The handover procedure (negotiation between the source cell and the candidate target cell and provision of a handover command to the UE via the source cell) may be triggered by the measurement report. The serving cell configures the UE with measurement events (conditions) associated with the measurement configuration. If such measurement events are met, the UE generates a measurement report comprising the measured quantity (e.g. signal strength) of one or more detected cells (serving and/or neighbor cells). The UE then sends the measurement report to its serving cell so that the serving cell can decide whether to initiate the handover procedure to any reported neighbor cells. The measurement event that triggers the measurement report may use the same conditions (e.g., formulas) as described above. However, the threshold value Y in the condition for measurement report triggering may be selected to be lower than the threshold value X in the handover execution condition. This allows the serving cell to prepare for handover when an early measurement report is received and provides RRC connection reconfiguration with mobility control information (RRCConnectionReconfiguration with mobilityControlInfo) when the radio link between the source cell and the UE is still stable (neighbor cell is only Y dB better than the serving cell, where Y may be set to 0 for example). When the radio conditions are considered to be optimal for performing the handover, the performance of the handover is completed at a later point in time (when the neighboring cell is already X dB better than the serving cell, where X may be e.g. 3 dB).

Fig. 3 depicts an example with a serving cell and only one target cell. As shown, the UE 40 receives User Plane (UP) data from the serving cell 50 (step 0). Upon satisfaction of the measurement event (e.g., based on a 'low' threshold such as threshold Y), the UE 40 sends a measurement report to the serving cell 50 (step 1). The measurement report may include the measurement quantity of the target cell 60. Based on the report, the serving cell 50 in this example makes a decision to prepare the target cell 60 for potential handover (step 1A). Then, based on this decision, the serving cell 50 sends a handover request to the target cell 60 (step 2), which may occur earlier than the conventional handover procedure (if a low threshold for measurement reporting is given). In the case where the handover request is sent early in this way, this may be referred to as an "early HO request" as shown in fig. 3. The target cell 60 accepts the handover in response to the request and establishes an RRC configuration for the UE for use with the target cell 60 (step 2A). Then, the target cell 60 transmits a handover confirm including the constructed RRC configuration to the serving cell 50 (step 3). The serving cell 50 correspondingly sends a conditional handover command to the UE 40, which commands the UE 40 to handover to the target cell 60 in response to the satisfaction of the condition (step 4). The condition may be based on a "high threshold" (e.g., threshold X) that is higher than a low threshold that triggers a measurement report. When the measurement of the target cell 60 satisfies the handover condition (e.g., based on a high threshold), the UE 40 autonomously triggers a pending conditional handover to the target cell 60 (step 4A). In this regard, the UE 40 performs synchronization and random access with the target cell 60 (step 5), and confirms handover to the target cell 60 (step 6). After completion of the handover signaled to the serving cell 50 (step 7), the target cell 60 may provide user plane data to the UE (step 8).

In practice, however, there may often be many cells or beams for which the UE reports as possible candidates based on its previous Radio Resource Management (RRM) measurements. The network may then have the right to issue conditional switch commands for several of these candidates. The RRC connection reconfiguration of each of these candidates may be different, for example, in terms of HO execution conditions (reference signal to be measured and threshold to be exceeded) and in terms of random access preambles to be transmitted when the conditions are met.

The RRC connection reconfiguration may be "delta" of the current configuration of the UE, i.e. the RRC connection reconfiguration message does not include all parameters determining the UE configuration, but only parameters that have changed compared to the current configuration of the UE. In some embodiments, the UE will apply RRC connection reconfiguration messages in the order in which it receives them due to the nature of the Radio Link Control (RLC) protocol and the order in which they were generated and sent by the network.

The UE can explicitly determine how to apply the (incremental) configuration provided in the conditional handover command so that the configuration used by the UE later is consistent with the network expectations. Thus, in some embodiments, the trigger conditions associated with the HO command sent to the UE should evaluate the measurements and trigger a handover when these conditions are met. But since the HO command configuration may be an increment of the current RRC configuration of the UE, one or more embodiments address how to handle subsequent RRC connection reconfiguration messages arriving from the source cell if the UE has not performed a handover.

When the UE receives the "conditional HO command", it may interpret the RRC connection reconfiguration with mobility control information as an increment of its current configuration (unless it is a complete configuration message). It may in principle determine the resulting target configuration immediately after receiving the command, but only apply/execute the configuration if the associated conditions are met. During the time the UE evaluates the condition, it may continue to operate according to its current serving cell RRC configuration, i.e., without applying the conditional HO command.

When the UE determines that the condition is satisfied, it disconnects from the serving cell, applies the condition HO command, and connects to the target cell. Once the UE applies RRC connection reconfiguration including mobility control information, it should not process any subsequent RRC connection reconfiguration messages received before HO execution.

However, the UE may stay in the source cell until the HO condition is satisfied. During this time, the source cell should have means to perform further reconfiguration of the UE to change the UE operation in the current serving cell or to issue (conditional or immediate) a handover to another target cell. In this case, the previously received conditional HO command cannot be applied to the increment of the updated serving cell configuration so far (after the RRC connection reconfiguration is applied) because the original conditional HO command is constructed as the increment of the previous RRC configuration (i.e., before the serving cell reconfiguration command is received).

The simplest solution is for the UE to discard the pending conditional HO command upon receiving a subsequent RRC connection reconfiguration from its source cell. But this means that the source eNB must reissue the conditional HO command to the UE; now as an increment of the updated source cell configuration. However, since the RRC configuration in the conditional HO command is constructed by the target eNB, this would mean additional inter-eNB signaling and subsequent Uu signaling.

One or more embodiments provide an efficient way to handle subsequent RRC reconfiguration and configuration towards multiple cells when using a conditional HO solution.

In some embodiments, the UE does not simply discard all pending (unsatisfied) conditional HO commands upon receiving a subsequent RRC connection reconfiguration of the current serving cell, but rather applies the subsequent RRC connection reconfiguration of the serving cell as an increment of the current configuration of the serving cell; and it retains the previously received pending conditional HO command for one or more target cells, i.e. the target cell configuration associated with the target cell is not affected by the subsequent RRC connection reconfiguration of the serving cell.

Subsequent RRC connection reconfiguration

To avoid additional signaling between enbs and towards the UE, the UE may not discard the conditional HO command when receiving a subsequent RRC connection reconfiguration of the serving cell.

According to a first example embodiment, upon receiving a subsequent RRC connection reconfiguration of a current serving cell, the UE applies the subsequent RRC connection reconfiguration of the serving cell as an increment of the current configuration of the serving cell; and it retains the previously received pending conditional HO command for the one or more target cells, i.e. the target cell configuration associated with the one or more target cells is not affected by the subsequent RRC connection reconfiguration of the serving cell.

In an example embodiment according to the first example embodiment, when the UE receives a conditional HO command or when the UE receives a subsequent RRC connection reconfiguration, the UE determines a target cell configuration from the current RRC configuration of the serving cell (before applying the newly received RRC connection reconfiguration) and from the incremental configuration received in the conditional HO command; and the UE stores and retains the determined target cell configuration.

The RRC connection reconfiguration of the source cell received after the conditional HO command for the target cell thus only affects the operation towards the source cell and not the configuration towards the target cell.

In another example embodiment according to the first example embodiment, the UE stores the received conditional HO command and the current RRC context of the serving cell (assuming that RRC connection reconfiguration is provided as an increment of the current serving cell configuration). If the UE receives a subsequent RRC connection reconfiguration for the source cell, it applies the reconfiguration but leaves the stored current RRC context of the serving cell unaffected. When the trigger condition is satisfied, the UE determines a target cell configuration from the stored serving cell configuration and the delta received in the "conditional HO command" and then uses the configuration when performing HO.

Updating conditional HO commands for target cells

In another example embodiment, the network may decide to provide a new updated RRC connection reconfiguration in the conditional HO command of the target cell for which it has previously provided the conditional HO command. Correspondingly, if the UE receives a conditional HO command for a target cell for which it already has a pending conditional HO command, it determines a target cell configuration based on its current serving cell configuration and the "delta" in the HO command and uses that configuration for the target cell.

In another example embodiment, the network may indicate to the UE in an updated conditional HO command whether the included configuration is an increment of the current serving cell configuration or an increment of a previously determined and reserved configuration of the target cell. Correspondingly, the UE determines a new target cell configuration by applying the reconfiguration in the received updated conditional HO command as an increment of its current serving cell configuration or as an increment of a previously determined target cell configuration.

In another example embodiment, the network may provide the UE with updated conditions in the HO command only for the cell of the target cell for which it has previously provided the conditional HO command. If the UE receives such a conditional HO command with new conditions but without a (new) RRC connection reconfiguration for the target cell it already has a pending conditional HO command, it retains the previously received RRC connection reconfiguration but associates the previously received RRC connection reconfiguration with the received updated conditions.

In an example embodiment according to any of the preceding example embodiments, the network may provide an updated configuration of pending conditional HO commands. This may require updating one of a set of allowed target cell beams or a random access configuration for accessing the target cell.

Validity of extended conditional HO commands

The serving eNB operates a serving cell (which may be referred to as a source cell for handover). The target eNB operates the neighbor cell to which the UE should perform handover. In this case, then, the neighboring cell may also be referred to as a target cell for handover. The serving eNB may require the target eNB to extend the conditional HO command validity and if authorized by the target eNB, send a new time limit to the UE for the conditional HO command extending the validity time, i.e. extending the period of time during which the UE should evaluate the conditional HO command and may trigger a HO if the condition is met.

If the UE receives such a conditional HO command with a new active time but without a (new) RRC connection reconfiguration for the target cell it already has a pending HO command, it may keep the previously received RRC connection reconfiguration but associate the previously received RRC connection reconfiguration with the updated active time received.

Drop conditional HO command

The source cell may discard any outstanding conditional HO in the UE at any time. If the UE receives a command indicating that the previously received conditional HO command for the target cell is no longer valid, the UE may discard the previously received RRC connection reconfiguration and associated conditions. In some embodiments, the UE may signal to the network that such cancellation is successful, meaning that the stored relevant RRC state information has been deleted.

Replacing conditional HO commands for the first target cell by conditional HO commands for the second target cell

In another example embodiment, the eNB decides that the potential target cell has to be changed based on RRM measurements. In this case, the source eNB provides a conditional HO command to the UE with the new target cell and indicates that the UE should discard the previously provided conditional HO command. Correspondingly, the UE should be ready to receive both a cancellation of a previously received pending HO command of the first target cell and a conditional HO command for a new/update of the second target cell. Such discarded commands will indicate to the UE to cancel the previously given HO command and to delete all stored relevant RRC state information. The command may be for all previously given conditional HO, given conditional HO or a specific target cell or cells from a list of cells sharing the same configuration given by RRC connection reconfiguration. In the latter case, the UE should maintain the stored relevant RRC state information unless all conditional HO commands for cells sharing the same configuration are cancelled. In some embodiments, the UE may signal to the network that a new conditional HO command has been received and that the cancellation of the indicated conditional HO has been successful.

In fig. 4, inter-eNB signaling is presented for this scenario. As shown, upon satisfaction of a measurement event (e.g., based on a 'low' threshold such as threshold Y), the UE 40 sends a measurement report to the serving gNB 50 (step 1). The measurement report may include a measurement of the first target gNB 60-1. Based on the report, the serving gNB 50 in this example makes a decision to prepare the first target gNB 60-1 for the potential handover (step 1A). Then, based on this decision, the serving gNB 50 sends a handover request to the first target gNB 60-1 (step 2), which may occur earlier (given a low threshold of measurement reports) than in a conventional handover procedure. In the case where the handover request is sent early in this way, it may be referred to as an "early HO request" as shown in fig. 4. The first target gNB 60-1 accepts the handover in response to the request and constructs an RRC configuration of the UE 40 for use with the first target gNB 60-1 (step 2A). The first target gNB 60-1 then sends a handover confirm to the serving gNB 50 that includes the constructed RRC configuration (step 3). The serving gNB 50 correspondingly sends a conditional handover command to the UE 40, which instructs the UE 40 to handover to the first target gNB 60-1 in response to satisfaction of the condition (step 4). The condition may be based on a "high threshold" (e.g., threshold X) that is higher than a low threshold that triggers a measurement report.

However, before the measurement of the first target gNB 60-1 satisfies the handover condition (e.g., based on a high threshold), the UE 40 sends another measurement report to the serving gNB50 (step 5), which includes the measurement quantity for the second target gNB 60-2. Based on the report, the serving gNB50 in this example makes a decision to prepare the second target gNB 60-2 for the potential handover (step 6). Based on this determination, the serving gNB50 then sends an early handover request to the second target gNB 60-2 (step 7). The second target gNB 60-2 accepts the handover in response to the request and constructs an RRC configuration of the UE 40 for use with the second target gNB 60-2 (step 8). The second target gNB 60-2 then sends a handover acknowledgement including the constructed RRC configuration to the serving gNB50 (step 9). The serving gNB50 correspondingly sends a conditional handover command to the UE 40, which instructs the UE 40 to handover to the second target gNB 60-2 in response to satisfaction of the condition (step 10). In this example, the latter conditional switch command is used to cancel the pending conditional switch to the first target gNB 60-1. Then, in some embodiments, the serving gNB50 may indicate to the first target gNB 60-1 that the handover request was canceled (step 11), e.g., so that the first target gNB 60-1 may free up any resources it reserved for potential handovers.

Thus, this example shows that based on RRM measurements, the serving eNB triggers HO negotiation towards gNB 1. The serving cell sends a conditional HO command to the UE in step 4. Later, based on the new measurements, the serving gNB decides to trigger HO negotiation towards the target gNB 2. The cancellation of the conditional HO command towards gNB2 and the conditional HO command towards gNB1 is sent towards the UE in step 10. Thereafter, the serving eNB notifies the gNB1 that the previous HO request was canceled.

In one embodiment, the UE replies to the source eNB with a handover complete message as a response to the conditional HO command RRC message. This confirms that the UE has successfully received the conditional HO command.

Multiple cells prepared

As described above, it may be desirable to provide the UE with HO conditions and configurations for several candidate target cells. When receiving conditional HO commands for multiple target cells, the UE evaluates the HO conditions of more than one candidate target cell and stores the configurations of those candidate target cells separately as described in the previous section. However, this solution may lead to additional complexity especially on the UE side, as the UE may need to store several configurations with exactly the same resulting configuration in the target cell.

Thus, in another example embodiment, the network informs in a conditional HO command that the RRC connection reconfiguration in the conditional HO command applies to several cells. That is, the same conditional HO command is applicable to a plurality of cells. When the UE receives such conditional HO command, it stores only one configuration associated with multiple target cells.

In another example embodiment, the network provides conditional HO commands with multiple cells and possibly multiple configurations. Upon receiving such a configuration, the UE stores the current serving cell RRC configuration (RRC context). When the HO is triggered, the UE derives a corresponding target cell configuration based on the source cell configuration stored at the time of receipt of the HO command and parameters provided in the conditional HO command.

Discarding pending conditional HO commands at handover

When the UE performs handover to a target cell, the target cell sends a path handover request to a Core Network (CN) on which the CN forwards newly arrived data to the target cell. Furthermore, the CN acknowledges the path switch request towards the target and the target informs the source cell that it can release the UE context. In addition to this program, the following is also proposed.

In another example embodiment, the source cell should inform other target cells (if any) that they have prepared a HO for the UE, they can release their preparation for the UE's inbound HO.

Similarly, the UE may already be configured with several conditional HO commands. When the condition of one of these HO is met, the UE performs a handover towards the target cell according to the associated RRC connection reconfiguration. According to one embodiment, the UE discards all other pending HO commands (if any) while performing mobility towards the target cell. This may be triggered by a conditional handover being met, but may also be triggered by an unconditional handover. And it may be a handover to a different cell or to the current serving cell (intra-cell HO).

Although early handover preparation aims to increase the likelihood of successful HO execution, there may still be cases where the UE triggers a HO to the target cell but the HO fails. In this case, the UE may be considered to discard conditional HO commands for other candidate target cells and configuration for the previous source cell too early. Thus, the following enhancements are proposed.

In another example embodiment, when executing the HO command, the UE retains other pending conditional HO commands (if any) until an RRC connection reconfiguration complete (rrcconnectionreconfiguration complete) message has been sent to the target cell (HO successful). If it does not receive an authorization to enable it to send RRC connection reconfiguration complete, it may continue to evaluate the conditions of other pending conditional HO commands and execute one of these pending conditional HO commands when their conditions are met.

In general, embodiments herein then include a method in a terminal operating in a wireless network. The method may be characterized by: receiving a conditional HO command; storing a current RRC configuration and a conditional HO command; selecting a target cell based on the condition; deriving a target cell configuration from the stored RRC configuration and a conditional HO command associated with the selected target cell; and transmitting the random access and RRC connection reconfiguration complete to the target cell.

As described above, some embodiments allow for efficient reconfiguration of source cell configurations while the UE maintains and evaluates pending conditional HO commands and target cell configurations associated with those pending conditional HO commands.

Note that the embodiments herein are applicable to any type of wireless communication system (e.g., long term evolution, broadband CDMA, GSM, wi-Fi, etc.) for switching between any type of links (e.g., cells, sectors, nodes, beams).

The network node herein is any type of node in the wireless communication system 10, such as in the access network 12 or the core network 14. A radio node herein is any type of node (e.g. a base station or a wireless communication device) capable of communicating with another node by radio signals. A radio network node is any type of radio node (e.g., a base station) within the access network 12. A wireless communication device or simply a wireless device is any type of radio node capable of communicating with a radio network node or another wireless communication device by radio signals. Thus, wireless communication devices may refer to machine-to-machine (M2M) devices, machine-type communication (MTC) devices, narrowband internet of things (NB-IoT) devices, and so forth. The wireless device may also be a User Equipment (UE), however, it should be noted that the UE does not necessarily have a "user" in the sense of the person owning and/or operating the device. A wireless device may also be referred to as a radio, a radio communication device, a wireless terminal, or simply a terminal-unless the context indicates otherwise, the use of any of these terms is intended to include a device-to-device UE or device, a machine-to-machine communication enabled device, a wireless device equipped sensor, a wireless enabled desktop computer, a mobile terminal, a smart phone, a notebook embedded equipment (LEE), a notebook mounted device (LME), a USB dongle, a wireless client device (CPE), and the like. In the discussion herein, the terms machine-to-machine (M2M) device, machine Type Communication (MTC) device, wireless sensor, and sensor may also be used. It should be appreciated that these devices may be UEs, but are generally configured to transmit and/or receive data without direct human interaction.

In an IOT scenario, a wireless communication device as described herein may be or may be included in a machine or device performing monitoring or measurements, and the results of such monitoring measurements sent to another device or network. Specific examples of such machines are power meters, industrial machines, or household or personal appliances, such as refrigerators, televisions, personal wearable devices (e.g. watches), etc. In other scenarios, a wireless communication device as described herein may be included in a vehicle and may perform monitoring and/or reporting of an operating state of the vehicle or other functions associated with the vehicle.

Note that the wireless device 16 as described above may perform the method of fig. 2 and any other processes herein by implementing any functional means or units. In one embodiment, for example, wireless device 16 includes corresponding circuitry configured to perform the steps shown in fig. 2. In this regard, the circuitry may comprise circuitry dedicated to performing the particular functional processing and/or one or more microprocessors in conjunction with memory. In embodiments employing memory (which may include one or more types of memory, such as Read Only Memory (ROM), random access memory, cache memory, flash memory devices, optical storage devices, etc.), the memory stores program code that, when executed by one or more processors, performs the techniques described herein.

Fig. 5A, for example, illustrates a wireless device 16 in accordance with one or more embodiments. As shown, the wireless device 16 includes processing circuitry 300 and communication circuitry (communication circuitry) 310. Communication circuitry 310 (e.g., in the form of a transmitter, receiver, transceiver, or radio frequency circuitry) is configured to transmit and/or receive information to and/or from one or more other nodes, e.g., via any communication technology. Such communication may occur via one or more antennas internal or external to the wireless device 16 as shown. The processing circuit 300 is configured to perform the processing described in fig. 2, for example, by executing instructions stored in a memory (MEM) 320. In this regard, the processing circuit 300 may implement particular functional devices, units, or modules.

Fig. 5B illustrates a wireless device 16 in accordance with one or more other embodiments. As shown, the wireless device 16 implements various functional means, units, or modules, e.g., via the processing circuitry 300 in fig. 5A and/or via software code for implementing the functions described above (e.g., for implementing the steps in fig. 2). These functional devices, units or modules include, for example, a receiving module or unit 340 for receiving the conditional switch command 22, a storage module or unit 350 for storing the information 30, and an execution module or unit 360 for performing one or more operations based on the stored information 30.

Also in view of the above modifications and variations, fig. 6 generally illustrates the processing performed by network node 16 according to some embodiments. As shown, the process may include sending a command 22, the command 22 instructing the wireless communication device 16 to perform a link switch 24 from the source link 20A to the target link 20B in response to satisfaction of the condition (block 370). The command 22 may indicate a target link configuration 26 relative to a source link configuration 28. The process shown in fig. 6 may also include changing the source link configuration 28 after sending the command 22 (block 380). Furthermore, the processing may further include: after changing the source link configuration 28, an update command is sent indicating an updated target link configuration relative to the source link configuration prior to the source link configuration change (block 390).

In some embodiments, the method may further include signaling an update command indicating an updated target link configuration with respect to the source link configuration prior to the change in the source link configuration.

Note also that the network node 18 as described above may perform any of the processes herein by implementing any functional means or units. In one embodiment, for example, network node 18 includes corresponding circuitry configured to perform the steps of the processes (e.g., signaling) described herein. In this regard, the circuitry may comprise circuitry dedicated to performing the particular functional processing and/or one or more microprocessors in conjunction with memory. In embodiments employing memory (which may include one or more types of memory, such as Read Only Memory (ROM), random access memory, cache memory, flash memory devices, optical storage devices, etc.), the memory stores program code that, when executed by one or more processors, performs the techniques described herein.

Fig. 7A illustrates a network node 18 in accordance with one or more embodiments. As shown, network node 18 includes processing circuitry 400 and communication circuitry (communication circuitry) 410. Communication circuitry 410 (e.g., in the form of a transmitter, receiver, transceiver, or radio frequency circuitry) is configured to transmit and/or receive information to and/or from one or more other nodes, e.g., via any communication technology. Where the network node 18 is an access node (e.g., a base station), such communication may occur via one or more antennas internal or external to the network node 18 as shown. The processing circuit 400 is configured to perform the above-described processing, for example, by executing instructions stored in a memory (MEM) 420. In this regard, the processing circuit 400 may implement particular functional devices, units, or modules.

Fig. 7B illustrates a network node 18 in accordance with one or more other embodiments. As shown, the network node 18 implements various functional devices, units, or modules, e.g., via the processing circuitry 400 in fig. 7A and/or via software code. These functional means, units or modules comprise, for example, signaling modules or units 440 for performing signaling to/from the wireless device 16 as described above.

Those skilled in the art will also appreciate that embodiments herein also include corresponding computer programs.

The computer program comprises instructions which, when executed on at least one processor of a node (e.g. network node 18 or wireless device 16), cause the node to perform any of the respective processes described above. In this regard, a computer program may comprise one or more code modules corresponding to the apparatus or elements described above.

Embodiments also include a carrier containing such a computer program. The carrier may comprise one of an electronic signal, an optical signal, a radio signal, or a computer readable storage medium.

In this regard, embodiments herein also include a computer program product stored on a non-transitory computer readable (storage or recording) medium and comprising instructions that, when executed by a processor of a node, cause the node to perform as described above.

Embodiments also include a computer program product comprising program code portions for performing the steps of any of the embodiments herein when the computer program product is executed by a computing device. The computer program product may be stored on a computer readable recording medium.

The present invention may, of course, be carried out in other ways than those specifically set forth herein without departing from essential characteristics of the invention. The present embodiments are to be considered in all respects as illustrative and not restrictive, and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.

Claims (18)

1. A method performed by a wireless communication device (16) configured for use in a wireless communication system (10), the method comprising:

-receiving (100) a command (22) from an access node in the wireless communication system, the command (22) commanding the wireless communication device (16) to perform a link switch (24) from a source link (20A) to a target link (20B) in response to satisfaction of a condition, wherein the command (22) indicates a relative target link configuration for a source link configuration, the relative target link configuration comprising one or more parameter values different between an absolute target link configuration and the source link configuration and not comprising one or more parameter values identical between the absolute target link configuration and the source link configuration, and wherein the command indicates a condition to be satisfied for performing the link switch;

-storing (110) information (30) corresponding to the received target link configuration relative to the source link configuration, wherein the stored information (30) is associated with the condition, thereby enabling to determine the absolute target link configuration based on the stored information when the condition is met; and

-performing (120) a link handover (24) from the source link (20A) to the target link (20B) using the absolute target link configuration determined from the stored information (30) in response to the satisfaction of the condition.

2. The method of claim 1, wherein the command includes one or more changed parameter values that differ between the absolute target link configuration and the source link configuration.

3. The method of claim 2, wherein the stored information includes information regarding a source link configuration used upon receipt of the command (22) and one or more changed parameter values.

4. A method according to any one of claims 1 to 3, further comprising: the target link configuration (26) is determined from the stored information (30) in response to the condition being met.

5. The method of any of claims 1-2, further comprising: in response to receiving the command (22) or in response to determining that the source link configuration is to be changed, determining the target link configuration (26) indicated by the command (22), wherein the storing includes storing the determined target link configuration (26) as stored information (30).

6. A method according to any one of claims 1 to 3, further comprising: after storing the information (30), the source link configuration is changed and the stored information (30) is retained irrespective of the change in the source link configuration.

7. A method according to any of claims 1 to 3, wherein the target link configuration (26) specifies a random access configuration for random access to the target link (20B).

8. A method according to any one of claims 1 to 3, wherein the condition is met when the signal measurement for the target link (20B) exceeds the signal measurement for the source link (20A) by at least a predetermined amount.

9. A method according to any of claims 1 to 3, wherein the target link configuration (26) is a radio resource control, RRC, configuration for the target link (20B).

10. A wireless communication device (16) configured for use in a wireless communication system (10), the wireless communication device (16) comprising:

one or more processors; and

one or more memories storing instructions that, when executed by the one or more processors, cause the wireless communication device to:

-receiving (100) a command (22) from an access node in the wireless communication system, the command (22) commanding the wireless communication device (16) to perform a link switch (24) from a source link (20A) to a target link (20B) in response to satisfaction of a condition, wherein the command (22) indicates a relative target link configuration for a source link configuration, the relative target link configuration comprising one or more parameter values different between an absolute target link configuration and the source link configuration and not comprising one or more parameter values identical between the absolute target link configuration and the source link configuration, and wherein the command indicates a condition to be satisfied for performing the link switch;

-storing (110) information (30) corresponding to the received target link configuration relative to the source link configuration, wherein the stored information (30) is associated with the condition, thereby enabling to determine the absolute target link configuration based on the stored information when the condition is met; and

-performing (120) a link handover (24) from the source link (20A) to the target link (20B) using the absolute target link configuration determined from the stored information (30) in response to the satisfaction of the condition.

11. The wireless communication device of claim 10, wherein the command comprises one or more changed parameter values that differ between the absolute target link configuration and the source link configuration.

12. The wireless communication device of any of claims 10 to 11, wherein the stored information comprises information about a source link configuration used upon receipt of the command (22) and one or more changed parameter values.

13. The wireless communication device of any of claims 10-11, wherein the instructions cause the wireless communication device to further: the target link configuration (26) is determined from the stored information (30) in response to the condition being met.

14. The wireless communication device of any of claims 10-11, wherein the instructions cause the wireless communication device to further: in response to receiving the command (22) or in response to determining that the source link configuration is to be changed, determining the target link configuration (26) indicated by the command (22), wherein the wireless communication device is configured to: the determined target link configuration (26) is stored as stored information (30).

15. The wireless communication device of any of claims 10-11, wherein the instructions cause the wireless communication device to further: after storing the information (30) from which the target link configuration (26) indicated by the command (22) can be determined, the source link configuration is changed, and the stored information (30) is retained irrespective of the change in the source link configuration.

16. The wireless communication device of any of claims 10-11, wherein the target link configuration (26) specifies a random access configuration for random access to the target link (20B).

17. The wireless communication device of any of claims 10 to 11, wherein the condition is met when a signal measurement for the target link (20B) exceeds a signal measurement for the source link (20A) by at least a predetermined amount.

18. The wireless communication device of any of claims 10-11, wherein the target link configuration (26) is a radio resource control, RRC, configuration for the target link (20B).